KR20240054604A - Anchor for concrete members and construction method thereof - Google Patents

Abstract

The present invention provides a high-performance post support ring for concrete members that can be firmly fixed to the concrete member by exhibiting sufficient shear strength by installing a cylindrical shear support ring integrally protruding from the lower surface of the base plate installed on the existing concrete member to engage the concrete member. This is about installation anchors.
The high-performance post-installation anchor for a concrete member of the present invention includes a base plate installed in close contact with one surface of the concrete member; and a shear support ring formed on the lower surface of the base plate and integrally protruding from the base plate in a cylindrical shape. It is characterized by being composed of a.

Description

High-performance post-installation anchor for concrete members and construction method thereof {Anchor for concrete members and construction method thereof}

The present invention provides a high-performance post support ring for concrete members that exhibits sufficient shear strength and can be firmly fixed to the concrete member by installing a cylindrical shear support ring integrally protruding from the lower surface of the base plate installed on the existing concrete member to engage the concrete member. This is about installation anchors.

If the bending or shear strength of the existing member is insufficient due to aging of the reinforced concrete member or an increase in load, the member strength can be supplemented by attaching steel plates or carbon fiber plates to the existing structure.

However, reinforcing methods by increasing cross-section or stiffness are difficult to restore deflection that has already occurred.

Accordingly, the tension material tension method can be applied to members that require restoration of structural deflection.

The tension material tension method installs a tension material at an appropriate location in an existing structure and then introduces tension force through post-tensioning to the tendon material to simultaneously increase bending strength and shear strength to restore deflection.

When reinforcing an existing reinforced concrete member using the tension material tension method, a steel base plate is fixed and installed with an anchor plate on the existing reinforced concrete member, and then an anchor for anchoring the end of the tension member is attached to the base plate.

At this time, in order to fix the base plate to the reinforced concrete member, the concrete member is drilled and anchor bolts are installed, and the base plate is joined to the anchor bolt and then fixed with a nut (Patent Nos. 10-0414261, 10-0522866, etc.) ).

However, concrete members are vulnerable to shear forces acting on anchored anchor bolts. In other words, when a shear force acts on an anchor bolt fixed in concrete, a pryout failure occurs in which the concrete behind the anchor bolt falls off due to the lever action of the anchor bolt.

Therefore, it is possible to resist the shear force acting on the anchor due to shear friction at the joint surface of the base plate and the concrete member. For this purpose, an adhesive such as epoxy resin is applied to the front of the concrete member to temporarily fix the anchor plate, and the nuts fastened to the anchor bolts are tightened so that the anchor bolts act as shear friction bars and exert shear friction force.

However, according to the Shear and Torsion Design Standard for Concrete Structures (KDS 14 20 22: 2018), the friction coefficient on the shear force transmission surface for concrete made as a single piece is 1.4, whereas concrete anchored to structural steel by shear connectors or reinforcing bars has a coefficient of friction of 1.4. The coefficient of friction on the shear force transmission side is only 0.7. Moreover, because the steel anchor and the concrete member are dissimilar materials, it is difficult to expect sufficient and reliable shear strength at the joint surface.

Additionally, in order to exert shear friction at the joint surface, the nut must be tightened with a certain force using a tool such as an impact wrench to generate sufficient tension in the anchor bolt. However, if the anchor bolt diameter is large, it is difficult to use an impact wrench. Therefore, after pulling the anchor bolt with a bolt tensioner instead of an impact wrench, the worker has no choice but to tighten the nut by rotating it by hand.

However, this method is difficult to introduce sufficient tensile force if the length of the anchor bolt is not long enough. In addition, since the nut is tightened by manpower, tension loss is inevitable when fixing or releasing the bolt tensioner, making it difficult to demonstrate reliable shear strength.

In order to solve the above problems, the present invention relates to an anchor that is post-installed on an existing concrete member, and seeks to provide a high-performance post-installed anchor for a concrete member that exhibits sufficient shear strength and can be firmly fixed to the concrete member.

The present invention according to a preferred embodiment includes a base plate installed in close contact with one surface of a concrete member; and a shear support ring formed on the lower surface of the base plate and integrally protruding from the base plate in a cylindrical shape. It provides a high-performance post-installation anchor for concrete members, characterized in that it includes.

According to another preferred embodiment of the present invention, a through hole is formed at the center of the shear support ring in the base plate, one end is inserted into the anchor hole formed in the concrete member through the through hole, and the other end is connected to the base plate. Provided is a high-performance post-installation anchor for concrete members, characterized in that anchor bolts are provided to protrude from the upper surface.

The present invention according to another preferred embodiment provides a high-performance post-installation anchor for a concrete member, wherein an anchor hole reinforcement ring inserted into an anchor hole formed in the concrete member is protruding from the main surface of the bottom through hole of the base plate.

The present invention according to another preferred embodiment provides a high-performance post-installation anchor for a concrete member, wherein an engaging protrusion is formed on the upper surface of the base plate to protrude for engaging a fixture provided at an end of a reinforcing member.

The present invention according to another preferred embodiment provides a high-performance post-installation anchor for a concrete member, wherein the engaging protrusion is formed in a circular shape.

The present invention according to another preferred embodiment is a concrete member characterized in that a cap member is provided with a through hole formed on the upper part of the engaging protrusion to allow the anchor bolt to penetrate, and a fixing nut is fastened to the anchor bolt on the upper surface of the cap member. We provide high-performance post-installation anchors for use.

In the present invention according to another preferred embodiment, a spherical guide groove is formed on one side of the upper surface of the engaging protrusion and the lower surface of the cap member, and a spherical surface of a shape corresponding to the guide groove is formed on the other side, so that the guide groove Provided is a high-performance post-installation anchor for a concrete member, characterized in that a guide protrusion that adheres closely is formed to protrude.

The present invention according to another preferred embodiment is a tensioning device in which a through hole is formed in the upper part of the base plate so that the anchor bolt penetrates, and a plurality of jack bolts for pressing the upper surface of the base plate are coupled around the through hole. Provided is a high-performance post-installation anchor for a concrete member, characterized in that it is provided with a plate.

According to another preferred embodiment of the present invention, a plurality of jack bolt fastening holes through which the jack bolts pass are formed around the through hole of the tensioning plate, and the jack bolt fastening holes are positioned on the bottom of the tensioning plate. Provided is a high-performance post-installation anchor for a concrete member, characterized in that a receiving groove communicating with the jack bolt fastening hole is formed to accommodate a guide nut fastened to the end of the.

The present invention according to another preferred embodiment provides a high-performance post-installation anchor for a concrete member, wherein an outlet hole is formed through a base plate around the shear support ring.

The present invention according to another preferred embodiment is for constructing a high-performance post-installation anchor for the concrete member, including the steps of (a) forming a circular groove on one surface of the concrete member using a core bit; (b) applying epoxy resin to the anchor installation position on one side of the concrete member and injecting epoxy into the circular groove; and (c) installing the base plate in close contact with one surface of the concrete member so that the shear support ring is inserted and accommodated inside the circular groove; It provides a construction method of a high-performance post-installation anchor for a concrete member, comprising:

The present invention according to another preferred embodiment is to form an anchor hole at the center of the circular groove of the concrete member in step (a), and install an anchor bolt in the anchor hole before or after installation of the base plate. A method of constructing a high-performance post-installation anchor for a concrete member is provided.

According to the present invention, a cylindrical shear support ring formed to protrude integrally from the lower surface of a base plate installed on an existing concrete member is installed in engagement with the concrete member, thereby providing a high-performance concrete member that can be firmly fixed to the concrete member by exhibiting sufficient shear strength. Post-installation anchors can be provided.

Figure 1 is a perspective view showing a high-performance post-installation anchor for a concrete member of the present invention.
Fig. 2 is a bottom perspective view showing the anchor of Fig. 1;
Figure 3 is a perspective view showing the connection relationship between the anchor of Figure 1 and a concrete member.
Figure 4 is a cross-sectional perspective view showing the anchor of Figure 1 in an installed state.
Figure 5 is a diagram showing the concept of shear force resistance by anchors.
Figure 6 is a diagram showing the surface of action of shear resistance.
Figure 7 is a cross-sectional perspective view showing the coupling relationship of an embodiment provided with anchor bolts.
Figure 8 is a cross-sectional perspective view showing the anchor of Figure 7 in an installed state.
Figure 9 is a bottom perspective view showing an anchor provided with an anchor hole reinforcement ring.
Figure 10 is a cross-sectional view showing the anchor of Figure 9 in an installed state.
Figure 11 is a perspective view showing the coupling relationship of anchors provided with coupling protrusions.
Figure 12 is a cross-sectional view showing the anchor of Figure 11 in an installed state.
Figure 13 is a perspective view showing the coupling relationship of an anchor provided with a separable coupling protrusion.
Figure 14 is a perspective view showing the coupling relationship of an anchor provided with a cap member.
Figure 15 is a cross-sectional view showing the anchor of Figure 14 in an installed state.
Figure 16 is a perspective view showing anchors installed on both sides penetrating a concrete member.
Figure 17 is a cross-sectional view showing an anchor equipped with a guide groove and a guide protrusion in an installed state.
Figure 18 is a perspective view showing the coupling relationship of an anchor provided with a tensioning plate.
Figure 19 is a bottom perspective view showing the connection relationship between the tensioning plate, jack bolt, and guide nut.
Figure 20 is a cross-sectional perspective view showing the coupled state of the anchor shown in Figure 19.
Figure 21 is a perspective view showing an anchor provided with an outlet hole.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

Figure 1 is a perspective view showing a high-performance post-installation anchor for a concrete member of the present invention, Figure 2 is a bottom perspective view showing the anchor of Figure 1, and Figure 3 is a perspective view showing the coupling relationship between the anchor of Figure 1 and a concrete member. , FIG. 4 is a cross-sectional perspective view showing the anchor of FIG. 1 in an installed state. And Figure 5 is a diagram showing the concept of shear resistance by an anchor, and Figure 6 is a diagram showing the surface of action of shear resistance.

As shown in Figures 1 to 4, etc., the high-performance post-installation anchor for a concrete member of the present invention includes a base plate (41) installed in close contact with one surface of the concrete member (1); and a shear support ring 410 formed on the lower surface of the base plate 41 and integrally protruding from the base plate 41 in a cylindrical shape. It is characterized by being composed of a.

The present invention relates to an anchor (4) that is post-installed on an existing concrete member (1), and is intended to provide a high-performance post-installation anchor for a concrete member that can be firmly fixed to the concrete member (1) by exhibiting sufficient shear strength.

The present invention relates to a post-installation anchor (4) for a concrete member that is installed on an existing concrete member (1) for reinforcement, etc. to support shear force.

In the description, the upper part refers to the base plate (41) side, and the lower part refers to the concrete member (1) side.

3 and the like, the anchor 4 is shown as being installed on the upper surface of the concrete member 1, but the anchor 4 may also be installed on the lower surface or side of the concrete member 1.

The high-performance post-installation anchor (4) for a concrete member of the present invention includes a base plate (41) and a shear support ring (410).

The base plate 41 has a flat lower surface and is installed in close contact with one surface of the concrete member 1.

A fixture 3 for fixing the reinforcing member 2, such as a tension member, to the anchor 4 may be coupled to the base plate 41.

As shown in FIG. 1, etc., the fixture 3 may be formed integrally with the base plate 41. Alternatively, as shown in FIGS. 11, 13, etc., the fixture 3 may be manufactured separately from the base plate 41.

The shear support ring 410 has a cylindrical shape and is formed to protrude integrally with the base plate 41 on the lower surface of the base plate 41.

The shear support ring 410 is inserted and accommodated in a circular groove 11 pre-formed at a predetermined depth on one surface of the concrete member 1 (FIGS. 3 and 4).

Since the shear support ring 410 is inserted into the circular groove 11 of the concrete member 1 and physically engaged, not only the friction force (F ₁ ) at the joint surface of the base plate 41 and the concrete member 1 The shear force acting on the anchor 4 can be resisted by the shear strength (S) of the cross section of the shear support ring 410 (FIG. 5).

In addition, since the shear support ring 410 is inserted into the circular groove 11 of the concrete member 1, the inside and outside of the shear support ring 410 are supported by concrete.

At this time, the concrete of the lower part of the shear support ring 410 (on the drawing) and the cylindrical concrete inside the shear support ring 410 are integrally connected to each other, so they exert the shear strength (F ₂ ) of the concrete made as one piece (Figure 5). That is, the friction coefficient corresponds to 1.4. In addition, since the outside of the shear support ring 410 is also supported by concrete, the shear force can be resisted by the bearing force (B) of the shear support ring 410 and the concrete on the opposite side where the shear force acts.

Overall, with respect to the horizontal force (H) acting on the anchor (4) installed on the concrete member (1), the anchor (4) can be designed so that the smaller of S + F ₁ and F ₂ + B is greater than the horizontal force (H) ( min(S+F ₁ , F ₂ +B) > H).

Figures 6 (a) and (b) are views showing the surface of action of shear resistance, Figure 6 (a) is for the joint surface of the base plate 41 and the concrete member 1, and Figure 6 (a) is for the joint surface of the base plate 41 and the concrete member 1. b) is for the joint between the inner concrete and the outer concrete of the shear support ring 410.

In this way, the shear support ring 410 formed integrally with the base plate 41 is engaged with the concrete member 1, so that the friction force (F ₁ ) between the joint surface of the base plate 41 and the concrete, and the base plate 41 The shear force (S) of the joint between the shear support ring (410), the bearing pressure (B) of the shear support ring (410) and the concrete, and the shear friction (F ₂ ) between the inner concrete and the outer concrete of the shear support ring (410) are combined. This can greatly improve the joint strength between the post-installation anchor (4) and concrete.

FIG. 7 is a cross-sectional perspective view showing the coupling relationship of an embodiment provided with anchor bolts, and FIG. 8 is a cross-sectional perspective view showing the anchor of FIG. 7 in an installed state.

As shown in FIGS. 7, 8, etc., a through hole 411 is formed through the base plate 41 at the center position of the shear support ring 410, and one end penetrates the through hole 411 to form concrete. The anchor bolt 42 may be inserted into the anchor hole 12 formed in the member 1, and the anchor bolt 42 may be provided so that the other end protrudes from the upper surface of the base plate 41.

Since the anchor 4 is physically engaged and coupled to the concrete member 1 by the shear support ring 410, sufficient bonding strength can be achieved without a separate anchor bolt.

However, if the shear support ring 410 is low in height, the length at which the shear support ring 410 is engaged with the concrete member 1 becomes short. At this time, when a load acts on the anchor 4 in the direction normal to the concrete member 1, the anchor 4 may fall off the concrete member 1.

In addition, in order to apply shear force due to shear friction (F ₁ ) at the joint surface of the concrete member 1 and the base plate 41, a normal force must be applied to the joint surface.

Therefore, as with existing anchors, the base plate 41 is fixed to the concrete member 1 using the anchor bolt 42, and the fixing nut 43 is tightened to apply a tensile force to the anchor bolt 42, thereby forming the base plate 41. Shear friction can be exerted at the joint surface of the concrete member (1).

In addition, since the anchor bolt 42 is inserted into the anchor hole 12 drilled in the concrete member 1, additional shear force resistance is possible due to the shear strength of the anchor bolt 42 itself.

For this purpose, a through hole 411 is formed in the center of the base plate 41, and one end of the anchor bolt 42 is inserted into the anchor hole 12 formed in the concrete member 1 through the through hole 411. can do.

The other end of the anchor bolt 42 protrudes from the upper surface of the base plate 41, and a fixing nut 43 is fastened to the protruding anchor bolt 42 to tighten it.

Figure 9 is a bottom perspective view showing an anchor equipped with an anchor hole reinforcement ring, and Figure 10 is a cross-sectional view showing the anchor of Figure 9 in an installed state.

As shown in FIGS. 9 and 10, an anchor hole reinforcement ring 412 that is inserted into the anchor hole 12 formed in the concrete member 1 protrudes from the main surface of the bottom through hole 411 of the base plate 41. can be formed.

The concrete member (1) on which the anchor bolt (42) subjected to a shear load is installed is subjected to displacement that occurs in the opposite direction of the shear force due to the bearing stress of the front part of the anchor bolt (42) and the concrete and the lifting of the lower part of the anchor bolt (42). This may cause flyout failure, in which the rear concrete of the anchor (4) falls off.

Therefore, the anchor bolt 42 is inserted into the anchor hole 12 into which the anchor bolt 42 is inserted, and an anchor is attached to the lower part of the base plate 41 to prevent concrete cracks caused by the bearing stress of the anchor bolt 42 and improve the flyout strength. The hole reinforcement ring 412 can be formed to protrude.

The anchor hole reinforcement ring 412 prevents direct contact between the anchor bolt 42 and the concrete when shearing force is applied to the base plate 41, thereby preventing bearing stress from acting on the concrete.

In particular, since the concrete between the external shear support ring 410 and the internal anchor hole reinforcement ring 412 is restrained, the occurrence of cracks due to the bearing stress of the anchor bolt 42 can be effectively prevented.

In addition, the anchor hole reinforcement ring 412 extends from the base plate 41 toward the anchor hole 12. Therefore, even when the anchor hole 12 is tilted due to an error in the drilling angle, the anchor bolt 42 can be easily inserted by guiding the anchor bolt 42 toward the anchor hole 12.

Figure 11 is a perspective view showing the coupling relationship of the anchor provided with a coupling protrusion, and Figure 12 is a cross-sectional view showing the anchor of Figure 11 in an installed state.

As shown in FIGS. 11 and 12, a coupling protrusion 413 may be formed to protrude from the upper surface of the base plate 41 for coupling the fixture 3 provided at the end of the reinforcing member 2.

The fixture 3 for fixing the reinforcing member 2 to the anchor 4 may be formed integrally with the base plate 41 (see FIG. 1, etc.).

Alternatively, the fixture (3) may be configured separately from the base plate (41) to combine various types of reinforcing members (2).

In order to couple the fixture 3 configured separately from the base plate 41 to the base plate 41, a coupling protrusion 413 may be formed to protrude on the upper surface of the base plate 41.

In this case, as shown in FIG. 12, a coupling groove 32 into which the coupling protrusion 413 is inserted can be formed on the lower surface of the fixture 3.

The coupling protrusion 413 is inserted into the coupling groove 32 of the fixture 3 so that the fixture 3 and the base plate 41 can be coupled.

When the anchor bolt 42 is provided, a through hole 31 through which the anchor bolt 42 penetrates can be formed in the center of the coupling groove 32 of the fixture 3. In this case, with the other end of the anchor bolt 42 penetrating the through hole 31 and protruding toward the top of the fixture 3, the fixture nut 43 is fastened at the top of the fixture 3 to secure the fixture 3. can be fixed.

Figure 13 is a perspective view showing the coupling relationship of an anchor provided with a separable coupling protrusion.

As shown in FIGS. 11 and 13, the coupling protrusion 413 may be formed in a circular shape.

Regardless of the installation direction of the anchor 4, the engaging protrusion 413 can be formed in a circular shape so that the reinforcing member 2 can be installed in any direction.

When the coupling groove 32 is formed in the lower part of the fixture 3 and coupled to the coupling protrusion 413, if the coupling groove 32 is also formed in a circular shape, the fixture 3 can be freely centered around the coupling protrusion 413. It can rotate.

Meanwhile, as shown in FIG. 13, the engaging protrusion 413 can be configured separately from the base plate 41 and coupled to the base plate 41 by an anchor bolt 42.

And when the reinforcing member 2 is in the form of a wire, a ring-shaped fixture 3 can be formed at the end of the reinforcing member 2 and connected to the engaging protrusion 413.

At this time, a circular groove may be formed on the outer peripheral surface of the coupling protrusion 413 so that the ring-shaped fixture 3 is caught.

FIG. 14 is a perspective view showing the coupling relationship of anchors equipped with cap members, FIG. 15 is a cross-sectional view showing the anchor of FIG. 14 in an installed state, and FIG. 16 is a perspective view showing anchors installed on both sides penetrating a concrete member. am.

As shown in FIGS. 14 and 15, a cap member 44 is provided on the upper part of the engaging protrusion 413 and has a through hole 441 through which the anchor bolt 42 passes, and a fixing nut 43 is provided. It can be fastened to the anchor bolt 42 on the upper surface of the cap member 44.

The coupling protrusion 413 may penetrate the fixture 3 and be coupled to the fixture 3.

To this end, a coupling hole 33 may be formed through the center of the fixture 3, and a coupling protrusion 413 may be inserted into the coupling hole 33.

At this time, in order to prevent the fixture 3 coupled to the engaging protrusion 413 from being separated, a cap member 44 with a larger diameter than the engaging protrusion 413 may be installed on the upper part of the engaging protrusion 413.

The cap member 44 has a through hole 441 formed in the center through which the anchor bolt 42 passes.

The cap member 44 is fixed by a fixing nut 43 fastened to the anchor bolt 42 and supports the pressure of the fixing nut 43.

The fixture 3 is coupled to the outer peripheral surface of the engaging protrusion 413 between the base plate 41 and the cap member 44.

As shown in FIG. 16, the anchors 4 are provided on both sides of the concrete member 1 and can be simultaneously fixed by anchor bolts 42 penetrating the concrete member 1.

In FIG. 16, the fixture 3 is configured in the form of a U-shaped bar, and the inner end of the fixture 3 is connected to the engaging protrusion 413.

Figure 17 is a cross-sectional view showing an anchor equipped with a guide groove and a guide protrusion in an installed state.

As shown in FIG. 17, a spherical guide groove 414 is formed on one side of the upper surface of the engaging protrusion 413 and the lower surface of the cap member 44, and the guide groove 414 corresponds to the other side. A guide protrusion 442 that is formed in a spherical shape and comes into close contact with the guide groove 414 may be formed to protrude.

Since the base plate 41 is constructed in close contact with one surface of the concrete member 1, the upper surface of the base plate 41 is parallel to the surface of the concrete member 1.

As shown in (a) of FIG. 17, when the anchor bolt 42 is installed exactly perpendicular to the base plate 41, the entire contact area of the lower surface of the base plate 41 due to the tensile force of the anchor bolt 42 is the concrete member. (1) It can be pressed evenly toward the side to exert shear friction.

However, as shown in Figure 17 (b), if an error occurs in the drilling angle of the anchor hole 12, the anchor bolt 42 is installed at an angle from the normal direction of the base plate 41, so that the fixing nut 43 As a result, when the cap member 44 is pressed, the cap member 44 presses the engaging protrusion 413 unevenly. Accordingly, the bearing stress of the base plate 41 and the concrete is not evenly distributed, so shear friction cannot be properly exerted.

Therefore, by forming the cap member 44 with the engaging protrusion 413 of the base plate 41 and a spherical grounding structure, even if the anchor bolt 42 is constructed tilted due to an error in the drilling angle of the anchor hole 12, the anchor bolt The cap member 44 can press the base plate 41 evenly over the entire area by the tensile force of (42).

For this purpose, a spherical guide groove 414 is formed on the upper surface of the engaging protrusion 413, and a guide protrusion 442 that is inserted into the guide groove 414 and is spherically grounded is formed on the lower surface of the cap member 44. can do.

Conversely, a guide protrusion may be formed to protrude on the upper surface of the engaging protrusion 413, and a guide groove may be formed on the lower surface of the cap member 44.

Figure 18 is a perspective view showing the coupling relationship of an anchor provided with a tensioning plate.

As shown in FIG. 18, a through hole 451 is formed in the upper part of the base plate 41 to allow the anchor bolt 42 to pass through, and the base plate 41 is formed around the through hole 451. A tensioning plate 45 through which a plurality of jack bolts 46 for pressurizing the upper surface are coupled may be provided.

Figure 18 is another embodiment for accommodating the perforation angle error of the anchor hole 12.

If the anchor bolt 42 is installed tilted due to an error in the drilling angle of the anchor hole 12, the cap member 44 and the base plate 41 are not parallel to each other.

Even if the cap member 44 and the base plate 41 are not parallel, the tensioning plate 45 and the jack bolt ( 46) can be used.

The tensioning plate 45 is provided on the top of the base plate 41.

When the cap member 44 is provided, the tensioning plate 45 may be provided on top of the cap member 44.

A through hole 451 is formed in the center of the tensioning plate 45 through which the anchor bolt 42 passes, and a fixing nut 43 is fastened to the anchor bolt 42 at the top of the tensioning plate 45. It can be combined.

Although not shown in the drawing, a female thread is formed on the inner peripheral surface of the through hole 451 of the tensioning plate 45 so that the anchor bolt 42 is screwed together so that the tensioning plate 45 functions as a fixing nut. It may be possible.

A plurality of jack bolts 46 may be radially fastened around the anchor bolt 42 of the tensioning plate 45. To this end, a plurality of jack bolt fastening holes 452 may be formed around the through hole 451 of the tensioning plate 45.

A female thread is formed on the inner peripheral surface of the jack bolt fastening hole 452 so that the jack bolt 46 can be screwed to the jack bolt fastening hole 452.

Accordingly, by tightening the fixing nut 43 and then tightening the jack bolt 46 around the anchor bolt 42, the front end of the jack bolt 46 presses the base plate 41 or the cap member 44, etc. to secure the base. Stress may be evenly distributed over the entire lower surface of the plate 41.

That is, since a plurality of jack bolts 46 are radially arranged on the main surface of the anchor bolt 42, when the anchor bolt 42 is not perpendicular to the base plate 41 but is tilted due to a hole angle error, that is, tensioning Even when the plate 45 is not parallel to the base plate 41, the base plate 41 can be pressed evenly by properly tightening each jack bolt 46.

Three or more jack bolts 46 can be placed at equal angles, and drilling errors can be naturally adjusted by rotating the jack bolts 46 with the same torque.

The jack bolt 46 can use a relatively small diameter bolt and can rotate with a small torque. Therefore, workers can easily work with hand tools.

FIG. 19 is a bottom perspective view showing the connection relationship between the tensioning plate, jack bolt, and guide nut, and FIG. 20 is a cross-sectional perspective view showing the connection state of the anchor shown in FIG. 19.

19 and 20, a plurality of jack bolt fastening holes 452 through which the jack bolts 46 pass are formed around the through hole 451 of the tensioning plate 45, and the At the position of the jack bolt fastening hole 452 on the bottom of the tensioning plate 45, there is a receiving groove communicating with the jack bolt fastening hole 452 to accommodate the guide nut 460 fastened to the end of the jack bolt 46. 453) can be formed.

When installing the jack bolt 46 to the tensioning plate 45, if the jack bolt 46 is directly screwed into the jack bolt fastening hole 452, the tensioning plate 45 is manufactured from cast steel and subjected to tapping and heat treatment. is required, which increases production costs.

Therefore, in order to minimize the manufacturing cost of the tensioning plate (45) while using a ready-made jack bolt and nut set, the jack bolt fastening hole (452) is formed larger than the diameter of the jack bolt (46) so that the jack bolt (46) A receiving groove 453 may be formed in the lower part of the jack bolt fastening hole 452 to accommodate the guide nut 460 fastened to the lower end of the jack bolt 46.

The receiving groove 453 is formed in a shape corresponding to the guide nut 460 fastened to the lower end of the jack bolt 46, so that the guide nut 460 accommodated in the receiving groove 463 cannot rotate. .

Accordingly, when the jack bolt 46 rotates, the guide nut 460 does not rotate, and the jack bolt 46 is guided by the guide nut 460 and can move toward the base plate 41.

Figure 21 is a perspective view showing an anchor provided with an outlet hole.

As shown in FIG. 21, an outlet hole 415 may be formed through the base plate 41 around the shear support ring 410.

After filling the circular groove 11 with epoxy resin, the shear support ring 410 is inserted and fixed into the circular groove 11.

At this time, an outlet hole 415 may be formed in the base plate 41 to visually check whether the circular groove 11 is sufficiently filled with epoxy resin.

If the epoxy resin is properly filled, when the shear support ring 410 is inserted, the epoxy resin filled inside the circular groove 11 flows out to the upper part of the base plate 41 through the outlet hole 415.

In addition, during the installation of the anchor (4), the air inside the shear support ring (410) can escape through the outlet hole (415), so the base plate (41) can be easily adhered to the base surface of the concrete member (1). there is.

The method of constructing the high-performance post-installation anchor for a concrete member of the present invention relates to the method of constructing the high-performance post-installation anchor for a concrete member of the present invention described above with reference to FIGS. 1 to 21.

In the present invention, (a) first, a circular groove 11 is formed on one surface of the concrete member 1 using a core bit.

In step (a), the surface of the concrete member 1 where the anchor 4 is to be installed is removed from the paint and foreign substances and cleaned. Then, a circular groove 11 is formed on one surface of the concrete member 1 using a core bit.

Generally, when coring a concrete member (1) with a core bit, the core concrete is removed, but in the present invention, only the circular groove (11) is formed with a core bit and the inner core concrete is not removed.

The diameter, width, and depth of the circular groove 11 are formed to correspond to the diameter, thickness, and height of the shear support ring 410, respectively.

And (b) epoxy resin is applied to the installation position of the anchor 4 on one side of the concrete member 1, while epoxy is injected into the circular groove 11.

That is, epoxy resin is applied to one surface of the concrete member 1 to which the base plate 41 of the anchor 4 is to be attached, and the inside of the circular groove 11 is also filled with epoxy resin.

Finally, (c) the base plate 41 is installed in close contact with one surface of the concrete member 1 so that the shear support ring 410 is inserted and accommodated inside the circular groove 11.

At this time, the shear support ring 410 formed integrally with the lower surface of the base plate 41 is inserted and accommodated in the circular groove 11, and is fixed by epoxy resin.

Meanwhile, in step (a), an anchor hole 12 is drilled at the center of the circular groove 11 of the concrete member 1, and the anchor hole (12) is drilled before or after installation of the base plate 41. 12) The anchor bolt (42) can be installed.

When the anchor bolt 42 is installed, the anchor hole 12 may be drilled at the center of the circular groove 11 before or after forming the circular groove 11.

The anchor bolt 42 can be installed before or after installation of the base plate 41.

As shown in Figure 16, when the anchors 4 are installed on both sides of the concrete member 1 and the anchor bolts 42 penetrate the concrete member 1, the base plate 41 is installed first and then the anchor bolts 42 are installed. ) is preferably installed later.

If the diameter of the anchor bolt 42 is large, the anchor hole 12 can be drilled using a core bit. At this time, the anchor hole 12 and the circular groove 11 can be formed by changing only the core bit to a different diameter in the core bit equipment.

In order to construct the anchor hole 12 and the circular groove 11 in an exact concentric circle, the anchor hole 12 is first formed, and then a guide bar (not shown) is inserted into the anchor hole 12, and the core is guided by the guide bar. It is desirable to form the circular groove 11 by guiding the rotation center of the bit.

After completing the construction of the base plate 41 and the anchor bolt 42, the fixing nut 43 can be fastened to the portion of the anchor bolt 42 protruding from the upper surface of the base plate 41.

The fixing nut 43 is fastened to the anchor bolt 42 at the top of the base plate 41 or the cap member 44.

As the fixing nut 43 is tightened, a tensile force acts on the anchor bolt 42, so the joint surface between the base plate 41 and the surface of the concrete member 1 and the inner concrete of the shear support ring 410 and the shear support ring ( 410) Shear friction is exerted on the surface between the lower concrete.

1: Concrete member 11: Circular groove
12: Anchor hole 2: Reinforcement member
3: Fixture 31: Through hole
32: coupling groove 33: coupling hole
4: anchor 41: base plate
410: Leaflet support ring 411: Through hole
412: Anchor hole reinforcement ring 413: Combined protrusion
414: Guide groove 415: Outflow hole
42: Anchor bolt 43: Fixing nut
44: cap member 441: through hole
442: Guide protrusion 45: Tensioning plate
451: Through hole 452: Jack bolt fastening hole
453: Accommodating groove 46: Jack bolt
460: Guide nut

Claims (12)

A base plate (41) installed in close contact with one surface of the concrete member (1); and
A shear support ring 410 formed on the lower surface of the base plate 41 and integrally protruding from the base plate 41 in a cylindrical shape; A high-performance post-installation anchor for concrete members, comprising:
In paragraph 1:
A through hole 411 is formed through the base plate 41 at the center position of the shear support ring 410, and one end of the anchor hole 12 is formed in the concrete member 1 through the through hole 411. A high-performance post-installation anchor for a concrete member, characterized in that the anchor bolt (42) is inserted into and the other end protrudes from the upper surface of the base plate (41).
In paragraph 2,
A high-performance post-casting device for concrete members, characterized in that an anchor hole reinforcement ring 412 that is inserted into the anchor hole 12 formed in the concrete member 1 is protruding from the main surface of the bottom through hole 411 of the base plate 41. Installation anchor.
In paragraph 2,
A high-performance post-installation anchor for a concrete member, characterized in that a coupling protrusion 413 is formed on the upper surface of the base plate 41 to engage the fixture 3 provided at the end of the reinforcing member 2.
In paragraph 4,
The engaging protrusion 413 is a high-performance post-installation anchor for a concrete member, characterized in that it is formed in a circular shape.
In paragraph 4,
A cap member 44 is provided with a through hole 441 formed on the upper part of the engaging protrusion 413 to allow the anchor bolt 42 to penetrate, and a fixing nut 43 is attached to the anchor bolt on the upper surface of the cap member 44. A high-performance post-installation anchor for concrete members, characterized in that it is fastened to (42).
In paragraph 6:
A spherical guide groove 414 is formed on one side of the upper surface of the engaging protrusion 413 and the lower surface of the cap member 44, and on the other side, a spherical surface of a shape corresponding to the guide groove 414 is formed. A high-performance post-installation anchor for a concrete member, characterized in that a guide protrusion 442 that is in close contact with the guide groove 414 is formed to protrude.
In paragraph 2,
A through hole 451 is formed in the upper part of the base plate 41 to allow the anchor bolt 42 to pass through. A plurality of jacks are provided around the through hole 451 to press the upper surface of the base plate 41. A high-performance post-installation anchor for a concrete member, characterized in that it is provided with a tensioning plate (45) through which bolts (46) are penetrated.
In paragraph 8:
A plurality of jack bolt fastening holes 452 through which the jack bolts 46 pass are formed around the through hole 451 of the tensioning plate 45, and the jack bolt fastening on the bottom of the tensioning plate 45 A concrete member characterized in that a receiving groove 453 communicating with the jack bolt fastening hole 452 is formed at the position of the hole 452 to accommodate the guide nut 460 fastened to the end of the jack bolt 46. High-performance post-installation anchor for use.
In paragraph 1:
A high-performance post-installation anchor for a concrete member, characterized in that an outlet hole 415 is formed through the base plate 41 around the shear support ring 410.
It is intended to construct high-performance post-installation anchors for concrete members according to paragraph 1,
(a) forming a circular groove (11) on one surface of the concrete member (1) using a core bit;
(b) applying epoxy resin to the installation position of the anchor 4 on one side of the concrete member 1, while injecting epoxy into the circular groove 11; and
(c) installing the base plate 41 in close contact with one surface of the concrete member 1 so that the shear support ring 410 is inserted and accommodated inside the circular groove 11; A method of constructing a high-performance post-installation anchor for a concrete member, comprising:
In paragraph 11:
In step (a), an anchor hole 12 is drilled and formed at the center of the circular groove 11 of the concrete member 1,
A method of constructing a high-performance post-installation anchor for a concrete member, characterized in that installing an anchor bolt (42) in the anchor hole (12) before or after installing the base plate (41).

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